Intelligent Soldering Tip

ABSTRACT

A soldering tool may include a tool body comprising circuitry configured to interface with a controller, and a tip portion including a tip that is heated to melt solder and a handpiece that is graspable by an operator. The tip portion includes a heater and a sensor disposed in the tip. The tip portion includes a tip memory device disposed at the handpiece. The tip memory device is configured to store parametric data. The tip memory device is configured to exchange data with the controller.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. application No. 62/651,344filed Apr. 2, 2018, the entire contents of which are hereby incorporatedby reference in its entirety.

TECHNICAL FIELD

Example embodiments generally relate to soldering tools and, inparticular, relate to such a tool having an intelligent soldering tipfor improved monitoring.

BACKGROUND

Soldering tools, which are sometimes referred to as soldering irons orsoldering guns, are commonly used in electronics manufacturing andrepair activities along with other crafts and industries that involvemetalwork. Soldering tools are typically used to join metallic itemstogether at a joint by melting a filler metal (i.e., solder) into thejoint. The solder has a lower melting point than the items being joinedtogether at the joint, so the soldering tool needs to apply heatsufficient to melt the solder, but not hot enough to melt the itemsbeing joined.

Although a number of soldering tool designs have been proposed, a basicsoldering tool design includes at least a tip portion that is operablycoupled to a heater. The tip portion may, due to operation of theheater, become hot enough to melt the solder that contacts the tipportion. The tip portion may, in some cases, beremovable/interchangeable so that a number of different geometries(e.g., sizes and/or shapes) of tips or bits can be substituted forrespective different jobs. For example, some tip geometries (or shapes)may include a fine conical tip, a tapered chisel tip, a pyramid tip, atriangular flat face tip, a wide flat face tip, etc., where differentsizes may further be available within each respective shape category.

For a typical soldering tool, it is not possible to detect or otherwisedetermine the geometry of the tip that has been selected. Thus, thesoldering tool itself essentially treats all tips or bits the same.Accordingly, different tip temperatures may be experienced at therespective different tips, and soldering performance may vary.Additionally, values or parameters relating to lifetime performance ofeach tip cannot be determined.

As can be appreciated from the limitations described above, it may bedesirable to improve soldering tool designs. For example, improvementsin soldering tool design may enable better determination of tiptemperatures and therefore also better performance and tracking of thelifetime operation of the tip.

BRIEF SUMMARY OF SOME EXAMPLES

Some example embodiments may enable the provision of an intelligentsoldering tip that improves the overall functioning of typical solderingtools.

In an example embodiment, a soldering tool may be provided. Thesoldering tool may include a tool body comprising control circuitryconfigured to interface with a controller, and a tip portion including atip that is heated to melt solder and a handpiece that is graspable byan operator. The tip portion includes a heater and a sensor disposed inthe tip. The tip portion includes a tip memory device disposed at thehandpiece. The tip memory device is configured to store parametric datagathered by the sensor. The tip memory device is configured to exchangedata with the controller.

In another example embodiment, a tip portion for a soldering tool isprovided. The soldering tool may include a tool body having controlcircuitry configured to interface with a controller. The tip portion mayinclude a tip that is heated to melt solder based on operation of aheater, and a handpiece that is graspable by an operator. A sensor maybe disposed in the tip proximate to the heater. The tip memory devicemay be disposed at the handpiece. The tip memory device may beconfigured to store parametric data gathered by the sensor and exchangedata with the controller.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

Having thus described some example embodiments in general terms,reference will now be made to the accompanying drawings, which are notnecessarily drawn to scale, and wherein:

FIG. 1 illustrates a soldering tool structure that may be useful inconnection with providing an intelligent soldering tip portion accordingto an example embodiment;

FIG. 2 illustrates a block diagram of the soldering tool according to anexample embodiment;

FIG. 3 illustrates two examples of tip portions having different tiplengths in accordance with an example embodiment; and

FIG. 4 illustrates a side view and partial cut-away view of the tipportion of a robotic system in accordance with an example embodiment.

DETAILED DESCRIPTION

Some example embodiments now will be described more fully hereinafterwith reference to the accompanying drawings, in which some, but not allexample embodiments are shown. Indeed, the examples described andpictured herein should not be construed as being limiting as to thescope, applicability or configuration of the present disclosure. Rather,these example embodiments are provided so that this disclosure willsatisfy applicable legal requirements. Like reference numerals refer tolike elements throughout. Furthermore, as used herein, the term “or” isto be interpreted as a logical operator that results in true wheneverone or more of its operands are true. As used herein, operable couplingshould be understood to relate to direct or indirect connection that, ineither case, enables functional interconnection of components that areoperably coupled to each other.

As indicated above, some example embodiments may relate to the provisionof a soldering tool that includes an intelligent tip portion. Asoldering tool employing the intelligent tip portion of exampleembodiments may include, for example, capabilities for determining thetip temperature of various different tip types or geometries. Accurateparametric data may therefore be recorded for the tip portion so thatvarious life cycle determinations can be made for the tip portion.

FIG. 1 illustrates a soldering tool 100 according to an exampleembodiment. As shown in FIG. 1, the soldering tool 100 of an exampleembodiment may include a tip portion 110 that integrates a tip 112 (orbit) together with a handpiece 114 in a single structure. The tip 112may extend forward of the handpiece 114, generally in line with alongitudinal axis of the tip portion 110. The handpiece 114 may haveinsulated grips disposed thereon on an external surface thereof.Internally, the handpiece 114 may include electronic components forinterfacing with or otherwise driving operation of the soldering tool100 with respect to providing power for heat generation at the tip 112.The tip portion 110 may also include a plug pin 116 disposed on anopposite side of the handpiece 114 relative to the tip 112. The plug pin116 may be coaxial with the tip 112 relative to the longitudinal axis ofthe tip portion 110. The plug pin 116 may include a first electricalconnection 117 for power, a second electrical connection 119 for ground,and a third electrical connection 121 for communicating data.

In an example embodiment, the soldering tool 100 may also include a toolbody 120 that is configured to mate with the tip portion 110. Inparticular, for example, the tool body 120 may include plug connector122 configured to receive the plug pin 116 of the tip portion 110.Meanwhile, the tool body 120 may include electronics (e.g., controlcircuitry 230 discussed below in reference to FIG. 2) for directingoperation of the components of the tip portion 110, and a power cord orcable 124 that operably couples the tool body 120 to a power unit 130.Thus, the power unit 130 may provide power and/or control signals to thetool body 120 via the cable 124. The plug connector 122 of the tool body120 may include electrical interfaces that enable the power and/orcontrol signals to be passed on to the tip portion 110 via the plug pin116 when the plug pin 116 is inserted into and operably coupled to theplug connector 122.

FIG. 2 illustrates a block diagram of various components of thesoldering tool 100 in accordance with an example embodiment. Referringnow to FIG. 2, the power unit 130 may include processing circuitry inthe form of a central processing unit (CPU) 200 or other controller. TheCPU 200 may be configured to perform data processing, control functionexecution and/or other processing and management services for the powerunit 130 specifically, and other portions of the soldering tool 100generally, according to an example embodiment. In some embodiments, theCPU 200 may be embodied as a chip or chip set. In other words, the CPU200 may comprise one or more physical packages (e.g., chips) includingmaterials, components and/or wires on a structural assembly (e.g., abaseboard). In an example embodiment, the CPU 200 may include one ormore instances of a processor and memory that may be in communicationwith or otherwise control a various components to which the CPU 200 isoperably coupled (e.g., the tool body 120, the tip portion 110, andcomponents thereof).

The power unit 130 may provide power to the tip portion 110 via the toolbody 120. In this regard, for example, a power line 202 may extend fromthe power unit 130 and through the tool body 120. The power line 130 maybe interruptible at the interface between the tip portion 110 and thetool body 120 (e.g., by removing the plug pin 116 from the plugconnector 122). However, when the plug pin 116 is inserted into the plugconnector 122, the power line 202 may be completed into the tip portion110 and extend to heater 210. A ground wire 212 may similarly extendfrom the heater 210 to the power unit 130 via the tool body 120. Theground wire 212 may also be interruptible in similar fashion to thepower line 202 as described above.

The heater 210 may be or include a resistive element that generates heatresponsive to the running of current therethrough. The heater 210 may bedisposed at or near the tip 112 of the tip portion 110 and may heatmetal in the tip 112 as the temperature of the heater 210 rises. In anexample embodiment, a sensor 220 may be disposed within the tip 112 aswell. The sensor 220 may be disposed proximate to the heater 210 tosense a temperature of the heater 210, and portions of the tip 112immediately adjacent to the sensor 220.

In an example embodiment, the CPU 200 may be operably coupled to controlcircuitry 230 disposed within the tool body 120. The control circuitry230 may include an analog-to-digital (AD) converter 232, a vibrationsensor 234, a memory device 236 (such as, for example, an EEPROM(electronically erasable programmable read-only memory)). The controlcircuitry 230 may be operably coupled to the CPU 200 via an I²C 240, twowire communication connection. Meanwhile, only a single wire (i.e.,connection wire 242) may operably couple the control circuitry 230 tothe sensor 220. The connection wire 242 may, in some cases, providecontinuous (or near continuous) feedback on temperature (or otherparameters) sensed by the sensor 220. Accordingly, the control circuitry230 may further include a converter 244 to convert from the I²C 240 tothe connection wire 242. In some cases, the control circuitry 230 mayalso include a switch 246 for powering lighting (e.g., light emittingdiode (LED) ring lighting) on the soldering tool 100 to indicate whenpower is applied to the heater 210. As can be appreciated from FIG. 2,the cable 124 may house the power line 202, the ground wire 212 and theI²C 240.

The connection wire 242 may also be interruptible in similar fashion tothe power line 202 and the ground wire 212 as described above. Moreover,the plug pin 116 and the plug connector 122 may include electricalinterfaces to operably couple the separate portions of the ground wire212, the power wire 202 and the connection wire 242 to each other whenthe plug pin 116 is mated with the tool body 120 via the plug connector122. Thus, for example, the control and parametric data communicatedbetween the CPU 200 and the control circuitry 230 may be provided overthe I²C 240, whereas control and parametric data communicated betweenthe control circuitry 230 and the sensor 220 may be provided over onewire in the form of the connection wire 242.

In an example embodiment, another memory device (e.g., tip memory 250)may be provided in the tip portion 110. In this regard, for example, thetip memory 250 may be operably coupled to both the control circuitry 230and the sensor 220 via the connection wire 242. Thus, temperaturefeedback is provided via the connection wire 242 as well as thecommunication of any other parameters, identifying information, etc.,that passes to and from the tip memory 250. As such, the tip memory 250(which may be embodied as an EEPROM as well in some cases) may providelocal storage for parameters (i.e., tip parameters) and/oridentification information regarding the tip portion 110. The tipparameters may include data indicative of measurements taken by thesensor 220 (which may be registered temporally to identify the timeassociated with each measurement), or any other parametric dataassociated with operation of the soldering tool 100 (e.g., power ontime, time above a threshold temperature, etc.). Thus, the tipparameters that can be stored locally at the tip portion 110 within thetip memory 250 may be very useful in determining a historical record ofthe operation of the tip portion 110. However, having the capability tostore such information in direct association with the tip portion 110itself also unlocks numerous other unique capabilities, as will bediscussed in greater detail below.

As mentioned above, the tip 112 of many different instances of the tipportion 110 can be differently shaped and/or sized. Given this potentialfor variability, it should be appreciated that applying the same amountof heat (and therefore potentially the same sensed temperature) at theheater 210 may result in different temperatures at the distal end of thetip 112. Consider for example, the two tip portions shown in FIG. 3. Inthis regard, first tip portion 300 and second tip portion 310 may eachhave substantially identical constructions with the exception that thefirst tip portion 300 has a first tip 320 that is longer than a secondtip 322 that is disposed on the second tip portion 310. Meanwhile, ineach case, the heater 210 and the sensor 220 may be disposed in roughlythe same location relative to the handpiece 114. However, a first tipextension portion 330 of the first tip portion 300 extends forward ofthe sensor 220 by a first distance (D1) that is longer than a seconddistance (D2) representing the amount of extension of a second tipextension portion 332 of the second tip portion 310. The differencebetween the first distance (D1) and the second distance (D2) may beunderstood to account for a temperature difference (T-Offset) at adistal end of the first tip 320 and the second tip 322 (i.e., where thetemperature at the distal end of the first tip 320 is likely lower thanthe temperature at the distal end of the second tip 322 for the sametemperature at the heater 210 (as recorded by the sensor 220)).Accordingly, for example, one or more temperature settings may beinserted into the heater 210 and the corresponding sensed temperature atthe sensor 220 can be recorded for each of the first tip 320 and thesecond tip 322. Meanwhile, an accurate measurement of the temperature atthe distal end of the tip (e.g., the first tip 320 and the second tip322) can also be made. The T-Offset for each of the tips (e.g., thefirst tip 320 and the second tip 322) can then be determined and storedin the respective instances of the tip memory 250 in the first andsecond tip portions 300 and 310. The T-Offset can also be updated sincethe tip memory 250 can be alternately written to and read from an numberof times. Thus, if a calibration is performed, old calibration data canbe replaced with new calibration data. Moreover, in some cases, ahistorical record of sequential calibration operations and T-Offsets orother calibration data generated may be stored in the tip memory 250.

By enabling the T-Offset for each tip portion to be stored in the tipmemory 250 of the corresponding tip portion, each tip portion can beinserted interchangeably into any tool body, and with any power unit,and communicate its respective T-Offset to the tool body and/or powerunit. The T-Offset can therefore act as calibration data to enable thetool body and/or power unit to provide specific targeted tiptemperatures regardless of the tip portion that is being used. Thus, forexample, if the operator has a power unit (e.g., power unit 130) thathas one or more temperature settings that can be selected, the selectionof a particular temperature setting by the operator can be used inconnection with the calibration data provided by the particular tipportion that is currently attached to the tool body and power unit toset the heater 210 at a temperature that will result in (afterconsidering T-Offset) the particular temperature setting at the distalend of the particular tip portion.

As can be appreciated from the description above, temperaturecalibration can occur based on specific knowledge of the characteristicsof the tip portion 110, and such calibration data may be stored locallyat the tip portion 110 in the tip memory 250 so that the tip memory 250can share the calibration data (for temperature) with the tool body 120and/or power unit 130. However, it should also be appreciated that anyof multiple measurable parameters of the tip portion 110 could also oralternatively be calibrated for in similar fashion. For example, controlparameters, life cycle data, or other measurable parameters related tooperation of the soldering tool 100 can be measured at individuallocations and at an instance of the sensor 220 that is configured tomeasure the corresponding parameter(s). The parameter(s) can then becompensated for (e.g., by defining respective parameter offsets) and thecalibration data associated with such compensation may be stored locallyat the tip portion 112. The calibration data may then be shared with thetool body 120 and/or power unit 130 for each and every individualinstance of the tip portion 112 so that calibrated operation of thesoldering tool 100 can be provided for any random tip portion that isinserted, so long as an instance of the tip memory 250 is able tocommunicate the corresponding calibration data to the tool body 120and/or power unit 120.

One of the parameters that can be stored within the tip memory 250 maybe a reference position of the distal end of the tip 112. In otherwords, the tip memory 250 may, for example, define an x-y-z referenceposition from any desirable reference point on the tip portion 110. Asshown in FIG. 4, a reference position 400 may be defined for the tipportion 110. The reference position 400 may be a known position that iscommon to every instance of the tip portion 110 (i.e., regardless of alength or shape of the tip 112). The distal end of the tip 112 may thenbe measured from the reference position 400 and an x-y-z referenceposition for the distal end of the tip 112 may be stored in the tipmemory 250. Thus, for example, if the tip portion 110 is inserted intothe tool body 120 of a particular instance of the soldering tool 100,the specific location of the distal end of the tip 112 may be known.This knowledge may be useful, for example, for robotic systems in whichthe soldering tool 100 operates under the control of a robotic arm orother mechanical operator. The CPU 200 may be able to know the exactposition (within a context defined using an x-y-z coordinate system) ofthe distal end of the tip 112 in order to reach joints under roboticcontrol.

Thus, for any of a number of different parameters, the tip portion 110can be interchangeable with different instances of the tool body 120and/or the power unit 130, and the tip portion 110 may share informationabout itself (i.e., calibration data or reference position data) toenable the CPU 200 to improve operation of the soldering tool 100 basedon specific knowledge about one or more parametric offsets or locationinformation provided by the tip portion 110 (and stored locally at thetip portion 110). However, other useful information may also be storedat the tip portion 110 within the tip memory 250 to further enableunique operations of the soldering tool 100.

In this regard, for example, in addition to (or as an alternative to)storing parametric data (e.g., calibration data or reference positiondata) that is uniquely descriptive of an individual instance of the tipportion 110, unique identification information (e.g., a tip identifier)may be stored in the tip memory 250. The tip identifier for anindividual instance of the tip portion 110 may allow parametric datastored at the tip memory 250 to be communicated to the tool body 120and/or power unit 130, or to other devices so that the parametric datacan be analyzed. As such, all of the parametric data extracted from theindividual instance of the tip portion 110 can be associated with thetip identifier of the individual instance of the tip portion 110. Thetip-identified data (i.e., parametric data that is associated with itsrespective tip identifier) may be analyzed to determine life cycle dataor other data that may be used to determine whether the useful life ofthe tip portion 110 is ended, or whether maintenance should beundertaken.

In some examples, the tip identifier (or a code or other data) of theindividual instance of the tip portion 110 may also or alternatively beused for performance of a security function. For example, the tool body120 and/or power unit 130 may be programmed to interrogate the tipmemory 250 of each tip portion inserted into the tool body 120. Theinterrogation may be useful to determine calibration data and/orreference position data as described above. Moreover, such data may alsobe provided in association with the tip identifier to enable analysis ofthe tip-identified data, as described above. However, the interrogationcould also be an enablement criteria for allowing operation of theindividual instance of the tip portion 110 with the tool body 120 and/orpower unit 130. For example, if the tool body 120 and/or power unit 130is interrogated and does not have a tip memory 250, no tip identifiermay be provided in response to the interrogation. The tool body 120and/or power unit 130 may, in response to a failed interrogation, notoperate with the tip portion 110 and, in some cases, may issue an alarm,warning, or message to indicate the reason for non-operation. If thetool body 120 and/or power unit 130 are provided with a list ofacceptable tip identifiers, the interrogation may (assuming the tipportion 110 has the tip memory 250) result in a return of the tipidentifier from the tip portion 110 so that the tool body 120 and/orpower unit 130 can compare the tip identifier received to the list ofacceptable tip identifiers. If the tip identifier received is on thelist of acceptable tip identifiers, operation of the tip portion 110with the tool body 120 and/or power unit 130 may be allowed. However, ifthe tip identifier received is not on the list of acceptable tipidentifiers, operation of the tip portion 110 with the tool body 120and/or power unit 130 may be prevented. As noted above, an alarm,warning or message may also be issued to inform the operator of thereason for non-operation. Accordingly, operation of the soldering tool100 with counterfeit tip portions may be prevented. As such, the tipidentifier may act as a unique serial number for quality checked orapproved equipment, and quality system operation can be enabled, andquality components can be traced.

Based on the descriptions above, it should be appreciated that exampleembodiments may provide a read/write enabled memory device (e.g., thetip memory 250) directly within the tip portion 110 of the solderingtool 100. However, the tip memory 250 is actually disposed in thehandpiece 114 of the tip portion 110 so that the temperature at the tipmemory 250 remains relatively constant due to the handpiece 114remaining cool during operation of the soldering tool 100. Thisplacement is likely to ensure fewer component failures and longercomponent life than any design that might, for example, place a memorychip within the tip 112 itself.

The tip memory 250 of an example embodiment may store calibration datafor various parameters (including temperature) to enable betterpredictability and performance of the soldering tool 100. Moreover, bystoring such calibration data in the tip portion 110, the tip portion110 can be removed and installed in any different sets of tool body 120and power unit 130 and still enable calibrated operation with the CPU200, which is located in the power unit 130. Example embodiments alsouse a “one wire” communication protocol in which the tip memory 250 usesa single wire to communicate with the CPU. Moreover, the communicationbetween components is hard wired (via plugging the plug pin 116 into theplug connector 122 to form a communication jack or socket) in exampleembodiments instead of providing wireless communication, which can beerror prone. In addition, wireless communication requires additionalwireless communication circuitry in both the sending component andreceiving component. By placing the CPU 200 in the power unit 130, andproviding wired communication means from the power unit 130 to the tipportion 110, smart communication between the CPU 200 and the tip memory250 can be achieved with fewer communication errors and with a simplerand cheaper design for the tip portion 110.

Example embodiments may provide precise control of tip temperaturesacross many different types (e.g., shapes and sizes) of tip portions(e.g., by using the sensor 220 and T-Offset). Other parameters,reference position data and life cycle data (such as predictivemaintenance-related data) can also be locally stored in connection withthe tip portion 110. The local storage can also be used to storesecurity information (e.g., tip identifiers or other codes) that can beused to prevent use of counterfeit tip portions. The tip identifiers mayalso provide unique identification numbers that can be used for totalprocess traceability. Calibration and customer initiated recalibrationcan each also be enabled by example embodiments.

Thus, according to an example embodiment, a soldering tool may beprovided. The soldering tool may include a tool body comprisingcircuitry configured to interface with a controller, and a tip portionincluding a tip that is heated to melt solder and a handpiece that isgraspable by an operator. The tip portion includes a heater and a sensordisposed in the tip. The tip portion includes a tip memory devicedisposed at the handpiece. The tip memory device is configured to storeparametric data (e.g., parametric properties, specific properties,maintenance/history/usage data, etc.) gathered by the sensor. The tipmemory device is configured to exchange data (including the parametricdata) with the controller.

In some cases, the tool described above may be augmented or modified byaltering individual features mentioned above or adding optionalfeatures. The augmentations or modifications may be performed in anycombination and in any order. For example, in some cases, the parametricdata may include temperature offset data indicating a temperaturedifference between a sensed temperature at the sensor and a temperatureat a distal end of the tip. In an example embodiment, the tip memorydevice may be configured to communicate the parametric data to thecontroller to enable the controller to operate the heater based on theparametric data. In some cases, the parametric data stored at the tipmemory device may be updateable. In an example embodiment, thecontroller may be disposed at a power unit operably coupled to the toolbody via a cable. In some cases, the cable may include a ground wire anda power line each of which are interruptible via removal of a plug pindisposed at the tip portion from a plug connector disposed at the toolbody. In an example embodiment, the circuitry may include a converterconfigured to transition from a two wire communication operably couplingthe circuitry to the controller to a one wire communication operablycoupling the circuitry to the tip memory and the sensor. In some cases,the tip memory device may be further configured to store a tipidentifier associated with an identity of the tip portion. In an exampleembodiment, the tip identifier may be communicated to the controller andthe controller is configured to enable operation of the tip portionbased on the tip identifier. In some cases, the parametric data may bestored in association with the tip identifier as tip-identified data,and the tip-identified data may define life cycle data associated withthe tip portion for determining maintenance to be performed on the tipportion. In an example embodiment, the tip memory device may storeinformation indicative of a location of a distal end of the tip portionrelative to a reference point disposed at a portion of the handpiece.

Many modifications and other embodiments of the inventions set forthherein will come to mind to one skilled in the art to which theseinventions pertain having the benefit of the teachings presented in theforegoing descriptions and the associated drawings. Therefore, it is tobe understood that the inventions are not to be limited to the specificembodiments disclosed and that modifications and other embodiments areintended to be included within the scope of the appended claims.Moreover, although the foregoing descriptions and the associateddrawings describe exemplary embodiments in the context of certainexemplary combinations of elements and/or functions, it should beappreciated that different combinations of elements and/or functions maybe provided by alternative embodiments without departing from the scopeof the appended claims. In this regard, for example, differentcombinations of elements and/or functions than those explicitlydescribed above are also contemplated as may be set forth in some of theappended claims. In cases where advantages, benefits or solutions toproblems are described herein, it should be appreciated that suchadvantages, benefits and/or solutions may be applicable to some exampleembodiments, but not necessarily all example embodiments. Thus, anyadvantages, benefits or solutions described herein should not be thoughtof as being critical, required or essential to all embodiments or tothat which is claimed herein. Although specific terms are employedherein, they are used in a generic and descriptive sense only and notfor purposes of limitation.

1. A soldering tool comprising: a tool body comprising circuitryconfigured to interface with a controller; and a tip portion including atip that is heated to melt solder and a handpiece that is graspable byan operator, wherein the tip portion comprises a heater and a sensordisposed in the tip, wherein the tip portion includes a tip memorydevice disposed at the handpiece, wherein the tip memory device isconfigured to store parametric data, wherein the parametric datacomprises temperature offset data indicating a temperature differencebetween a sensed temperature at the sensor and a temperature at a distalend of the tip, wherein the tip memory device is configured to exchangedata with the controller, and wherein the circuitry comprises aconverter configured to transition from a two wire communicationoperably coupling the circuitry to the controller to a one wirecommunication operably coupling the circuitry to the tip memory or thetip memory and the sensor.
 2. (canceled)
 3. The soldering tool of claim1, wherein the tip memory device is configured to communicate theparametric data to the controller to enable the controller to operatethe heater based on the parametric data.
 4. The soldering tool of claim3, wherein the parametric data stored at the tip memory device isupdateable.
 5. The soldering tool of claim 1, wherein the controller isdisposed at a power unit operably coupled to the tool body via a cable.6. The soldering tool of claim 1, further comprising a plug having afirst electrical connection for power, a second electrical connectionfor ground, and a third electrical connection for communicating theparametric data.
 7. The soldering tool of claim 1, wherein the tipmemory device is further configured to store a tip identifier associatedwith an identity of the tip portion, and wherein the tip identifier iscommunicated to the controller and the controller is configured toenable operation of the tip portion based on the tip identifier.
 8. Thesoldering tool of claim 7, wherein the parametric data is stored inassociation with the tip identifier as tip-identified data, and whereinthe tip-identified data defines life cycle data associated with the tipportion for determining maintenance to be performed on the tip portion.9. The soldering tool of claim 1, wherein the tip memory device storesinformation indicative of a location of a distal end of the tip portionrelative to a reference point disposed at a portion of the handpiece.10. The soldering tool of claim 1 further comprising a plug pin disposedon an opposite side of the handpiece from the tip, the plug pin beingconfigured to mate with the tool body, wherein the tip, the handpiece,and plug pin are disposed on a common lateral axis.
 11. A tip portionfor a soldering tool comprising a tool body comprising circuitryconfigured to interface with a controller, the tip portion comprising: atip that is heated to melt solder based on operation of a heater; and ahandpiece that maintains a temperature to be graspable by an operatorwhen the tip is heated to melt solder, wherein a sensor is disposed inthe tip proximate to the heater, wherein a tip memory device is disposedat the handpiece, wherein the tip memory device is configured to storeparametric data, wherein the parametric data comprises temperatureoffset data indicating a temperature difference between a sensedtemperature at the sensor and a temperature at a distal end of the tip,and wherein the tip memory device is configured to exchange data withthe controller.
 12. (canceled)
 13. The tip portion of claim 11, whereinthe tip memory device is configured to communicate the parametric datato the controller to enable the controller to operate the heater basedon the parametric data.
 14. The tip portion of claim 13, wherein theparametric data stored at the tip memory device is updateable.
 15. Thetip portion of claim 11, further comprising a plug having a firstelectrical connection for power, a second electrical connection forground, and a third electrical connection for communicating theparametric data.
 16. The tip portion of claim 11, wherein the tip memorydevice is further configured to store a tip identifier associated withan identity of the tip portion, and wherein the tip identifier iscommunicated to the controller and the controller is configured toenable operation of the tip portion based on the tip identifier.
 17. Thetip portion of claim 16, wherein the parametric data is stored inassociation with the tip identifier as tip-identified data, and whereinthe tip-identified data defines life cycle data associated with the tipportion for determining maintenance to be performed on the tip portion.18. The tip portion of claim 11, wherein the tip memory device storesinformation indicative of a location of a distal end of the tip portionrelative to a reference point disposed at a portion of the handpiece.19. The tip portion of claim 11, wherein the handpiece comprises aninsulated grip disposed on an external surface of the handpiece.
 20. Thetip portion of claim 11 further comprising a plug pin disposed on anopposite side of the handpiece from the tip, the plug pin beingconfigured to mate with the tool body, wherein the tip, the handpiece,and plug pin are disposed on a common lateral axis.